The invention relates to a switchgear cabinet for a wind power plant, having a U-shaped base plate, comprising a bottom and two side parts, two end plates connected to the base plate, and a cover, by means of which the switchgear cabinet is closed, wherein the end plates are lengthened beyond the side parts or longitudinal sides formed by the latter, or the end plates are each set back at a distance with respect to an outer edge of the base plate, such that the base plate and/or the end plates form tabs projecting outward, which are useful for the fixing of holders.

A panelboard system includes a panelboard, a first circuit breaker in the panelboard, a second circuit breaker in the panelboard, and an interlock assembly. The interlock assembly includes: an interlock panel, a first protrusion on the interlock panel and positioned above the first circuit breaker, a second protrusion on the interlock panel and positioned above the second circuit breaker, and a toggle bracket pivotally connected to the interlock panel at a pivot member between the first and second protrusions. The toggle bracket includes a first arm extending from the pivot member toward the first circuit breaker and a second arm extending from the pivot member toward the second circuit breaker.

A submersible electrical enclosure is for a switchgear assembly. The switchgear assembly includes a number of electrical switching apparatus. The submersible electrical enclosure includes: a plurality of sides defining an interior, the interior receiving each of the electrical switching apparatus, each side including: a conductive polymeric layer facing away from the interior, and an insulative polymeric layer molded to the conductive polymeric layer. The insulative polymeric layer faces the interior and substantially overlays the conductive polymeric layer.

A submersible electrical enclosure is for a switchgear assembly. The switchgear assembly includes a number of electrical switching apparatus. The submersible electrical enclosure includes: a plurality of sides defining an interior, the interior receiving each of the electrical switching apparatus, each side including: a conductive polymeric layer facing away from the interior, and an insulative polymeric layer molded to the conductive polymeric layer. The insulative polymeric layer faces the interior and substantially overlays the conductive polymeric layer.

An expandable bused elbow is provided for connecting modular metering equipment around an inside corner. The expandable bused elbow comprises an enclosure configured to fit in a gap between modular equipment. The enclosure has a box assembly with a sliding mechanism that enables expansion of the box assembly. The expandable bused elbow further comprises a first bussed interior assembly enclosed within the enclosure having a first bottom end and a second bussed interior assembly enclosed within the enclosure having a second bottom end. The first bussed interior assembly has a first bussing expansion mechanism that enables expansion of the first bussed interior assembly. The second bussed interior assembly has a second bussing expansion mechanism that enables expansion of the second bussed interior assembly. The expandable bused elbow further comprises a center corner assembly disposed in a middle space between the first bussed interior assembly and the second bussed interior assembly.

An expandable bused elbow is provided for connecting modular metering equipment around an inside corner. The expandable bused elbow comprises an enclosure configured to fit in a gap between modular equipment. The enclosure has a box assembly with a sliding mechanism that enables expansion of the box assembly. The expandable bused elbow further comprises a first bussed interior assembly enclosed within the enclosure having a first bottom end and a second bussed interior assembly enclosed within the enclosure having a second bottom end. The first bussed interior assembly has a first bussing expansion mechanism that enables expansion of the first bussed interior assembly. The second bussed interior assembly has a second bussing expansion mechanism that enables expansion of the second bussed interior assembly. The expandable bused elbow further comprises a center corner assembly disposed in a middle space between the first bussed interior assembly and the second bussed interior assembly.

The invention relates to a building automation device which can be recessed in an electrical box, which adapts to the various communication requirements, which comprises a communication module with a communication bus, an application module which implements the functionality of the device, and a bus connector between the two modules, in which said bus connector serves to supply and transfer data, the communication module comprises a first base, the application module comprises a second base, during use, second side faces of the second base are inserted into a first opening of the first base, and the first base is joined to the second base via first attachment means.

A housing for an electrical device comprises a housing bottom, a fastening element, and an unlocking element and is closeable by a housing cover. The housing bottom includes an elastically deformable connecting section to connect the housing to a machine, a technical system, or a building wall. The fastening element is disposed on an outer face of the connecting section and is connectable in a form-fitting and/or friction-fitting manner to a corresponding retaining element of the machine, the technical system, or the building wall. The unlocking element is disposed on an inner face of the connecting section and is operatively connected to the fastening element. The unlocking element is user actuatable only from an inside of the housing when the housing is open in order to release the form-fitting and/or friction-fitting connection of the fastening element to the retaining element of the machine, the technical system, or the building wall.

A housing for an electrical device comprises a housing bottom, a fastening element, and an unlocking element and is closeable by a housing cover. The housing bottom includes an elastically deformable connecting section to connect the housing to a machine, a technical system, or a building wall. The fastening element is disposed on an outer face of the connecting section and is connectable in a form-fitting and/or friction-fitting manner to a corresponding retaining element of the machine, the technical system, or the building wall. The unlocking element is disposed on an inner face of the connecting section and is operatively connected to the fastening element. The unlocking element is user actuatable only from an inside of the housing when the housing is open in order to release the form-fitting and/or friction-fitting connection of the fastening element to the retaining element of the machine, the technical system, or the building wall.

A prefabricated electrical module and system along with fabrication and installation methods are provided. The prefab electrical module includes a circuit breaker panel casing that houses multiple circuit breakers, and a chase extending upwardly from the panel casing that stows coiled lengths of homerun wiring attached to the circuit breakers. During transport, a temporary panel casing front cover protects the panel casing front, and a forwardly protruding guard cover with an upwardly projecting hoisting handle shields the front and top of the chase and wiring. During installation, a hoisting bracket is attached at the top of the stud bay into which the prefab electrical module will be installed. A drill-powered winch is then used to lift the module to the proper height in the bay. The panel casing, chase, wiring, and breakers remain in the wall. The hoisting bracket, temporary panel casing front cover, guard cover, drill, and winch are reusable.